update2: better implementation of calling the service constructor in resolveInstance() to follow operator new semantics.

i’ve become a big fan of the asynchronous module definition (AMD) pattern for managing dependencies between libraries and script files in large JavaScript projects. requirejs is my current favourite AMD library. TypeScript also provides excellent support for compiling and consuming modules in AMD-compatible formats.

i’ve also become a big fan of Ninject for its lightweight but very effective dependency injection library for .Net.

when looking for a simple Ninject-like dependency injection container for JavaScript, I attempted to find something that would be as familiar as using the requirejs/AMD approach. I thought about using the requirejs plugin API, but it is too resource/file oriented and would require resource naming contortions to support named identities for containers and object instances.

during my research I came across Coffeescripter’s post regarding dependency injection and IoC in javascript, and I admired the simple and straightforward modeling of the relationship between an array of dependency names and a constructor function. To me, this approach represented a very effective and lightweight way to adapt existing code for use in a dependency injection framework without having to make any modifications to that code. The constructor functions act as shims between the dependency injection framework and existing code, and work much the same way as the requirejs/AMD define() function does with its associated callback.

this inspired me to implement a dependency injection container using define()/require()-like semantics, including support for circular dependency resolution.

the source…

note: the source code provided has a few dependencies on ECMAScript 5 features, such as Array.isArray, Array.prototype.indexOf, and Function.prototype.bind. You can easily find replacements for these functions should you need to target an older platform.

i recently needed to be able to serialize a JavaScript Number to a 64-bit IEEE 754 floating point format.

there were two main challenges to overcome:

there is no universal way to get direct access to the bits that make up the JavaScript Number. DataView will change this, but it’s not available on IE9. So I needed to find a way to decode the JavaScript number into its constituent sign, exponent, and mantissa, with proper handling of denormalized values.

the mantissa, once calculated, is a 52-bit value, so we can’t use JavaScript’s bitwise operators to access the bits of the mantissa. The bitwise operators all coerce their arguments to 32-bit values.

jDataView is a library that has the ability to read 64-bit IEEE values from a buffer, and it has been recently updated to also support writing 64-bit IEEE values.

here is my solution to the problem until DataView becomes widely available.